KR20080114478A - Image display device - Google Patents

Abstract

An image display apparatus is provided to transmit an image signal to a signal processing circuit necessary for driving an image display apparatus without increasing costs for signal transmission. An image signal converting circuit(20) converts and outputs an image signal of the second image signal format by receiving an image signal of the first image signal format. A driving circuit(80) drives an image display panel(90) by the image signal of the second image signal format. A signal processing module(100) includes a signal processing circuit for performing signal processing for driving the driving circuit.

Description

Image display device {IMAGE DISPLAY DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image display device, and more particularly, to convert a video signal in a first video signal format into a video signal in a second video signal format, and to perform video signal conversion accompanied with an increase in dynamic range. It relates to an image display device.

Background Art Conventionally, color reproduction of television systems has been determined based on the characteristics of phosphors of the CRT, and standards for television signals and image display devices are limited to the color gamut of the sRGB color space. In order to express more vivid colors while maintaining compatibility with conventional television signals, the xvYCC standard, which is a new standard of the wide color gamut color space, has been defined (for example, "the wide color gamut color space for moving images" is defined. New Scale ", Korean Journal of Information and Information Media vol 60, No. 11, pp.1749-1754 (2006).

In the xvYCC standard, the luminance signal defined in the ITU-R BT.709 / 601 standard and the luminance signal defined in the ITU-R BT.709 / 601 standard are used to make the color space of the xvYCC standard higher compatible with the conventional ITU-R BT.709 / 601 standard. The relationship of the color space is also invariant in the xvYCC standard.

9 is a diagram showing photoelectric conversion characteristics of the ITU-R BT.7O9 standard and the xvYCC ₇₀₉ standard. In Fig. 9, in the ITU-R BT.709 standard, since RGB color signals are undefined at 0 or less and 1 or more, luminance chromaticity signals converted from color signals in this region are also undefined, and signal values may exist. Even if it is not used. The xvYCC ₇₀₉ standard extends the photoelectric conversion characteristics of the ITU-R BT.709 standard, extends conventional characteristics in the region where the color signal is 1 or more, and positive and point symmetry with respect to the origin in the region below 0 (minus). In this case, a wide color gamut is obtained by introducing a negative signal. In the RGB signal format, the signal range of 0 to 1 in the conventional ITU-R BT.7O9 standard is approximately three times larger in the signal range of approximately -1 to 2 in the xvYCC ₇₀₉ standard. That is, the dynamic range of the video signal is enlarged by about three times.

FIG. 10 is a conceptual diagram showing an area in which a video signal can be taken when the vertical axis is set to the luminance signal Y and the horizontal axis is set to the values of the chromaticity signals Cb and Cr. In FIG. 10, the central rhombic region 160 represents an area that can be taken by a video signal in the color gamut of the conventional sRGB color space. On the other hand, in the xvYCC color space, it extends to the area around the rhombus area 160, and 0.5 to 0.56 and -0.57 to 0.5 of the CbCr signal are also used as the video signal.

As described above, since the xvYCC standard realizes the information of the wide color gamut in a region not defined in the related art, the video signal of the sRGB color gamut in the conventional rhombus area 160 is the same as the conventional video signal. By using a camera or a display which can be used and reproduces the video signals in the wide-area extended area 170, the color of the video signals in these areas can also be expressed.

By the way, in the conventional television receiver, when receiving a YCbCr format television video signal, after performing television signal processing requiring screen format adjustment or the like, YCbCr / RGB conversion for converting from YCbCr format to RGB format is performed, and RGB converted video is performed. The signal was sent to the display module in the RGB input format. For example, in a plasma display device or a liquid crystal display device, a display module and an RGB converted video signal using a display module for RGB input are transmitted using a LVDS (Low Voltage Differential Signaling) interface or the like. there was.

11 is a block diagram showing an example of a circuit of the conventional plasma display device 250. In FIG. 11, the conventional plasma display apparatus 250 includes a television signal processing circuit 110 to which a YCbCr format television video signal is input, and a YCbCr / RGB image for converting a YCbCr format video signal into an RGB format video signal. And a signal conversion circuit 120 and a plasma display module 210. The plasma display module 210 further includes a plasma display panel 190 constituting an image display panel, a plasma display panel driving circuit 180 for driving the plasma display panel 190, and a plasma display panel driving circuit 180. And a plasma display signal processing circuit 200 which performs signal processing necessary to drive the < Desc / Clms Page number 5 > The plasma display panel driving circuit 180 includes an address electrode driving circuit (not shown), a sustain electrode driving circuit (not shown), and the like, and is a circuit for driving an electrode included in the plasma display panel 190. . The plasma display signal processing circuit 200 is a circuit which performs signal processing for converting a video signal in an RGB format into a driving format peculiar to the plasma display panel 190 in a subfield format. By this conversion, the plasma display panel drive circuit 180 can drive the plasma display panel 190.

Here, if the video signal conversion performed by the YCbCr / RGB video signal conversion circuit 120 is a conventional TV signal according to the ITU-R BT.709 / 601 standard, Y signals: 0 to 1, CbCr signals:- When it is 0.5 to 0.5, the RGB signal is set to 0 to 1. For example, when a 10-bit YCbCr signal is input to the YCbCr / RGB video signal conversion circuit 120, the YCbCr / RGB video signal conversion circuit 120 converts the signal into a 10-bit RGB signal and connects it to the connected LVDS interface or the like. It was configured to be transmitted and input to the plasma display panel signal processing circuit 200.

However, when the YCbCr format video signal of the xvYCC standard described in Non-Patent Document 1 is converted into the RGB format video signal, the signal variable width of the RGB signal is enlarged by about 3 times as described in FIG. In order to maintain compatibility with the prior art, it is necessary to increase the bit width of the RGB signal for transmitting the signal by about 2 bits. For example, what has been conventionally transmitted in each of 10 bits of RGB requires 12 bits in accordance with the xvYCC standard.

In this case, as in the configuration of the conventional plasma display apparatus 250 as shown in FIG. 11, a substrate on which the YCbCr / RGB video signal conversion circuit 120 is mounted, and a substrate on which the plasma display panel signal processing circuit 200 is mounted It is configured as a separate substrate, and transmission between them in an RGB format video signal increases the amount of transmission information of the video signal, resulting in an increase in the cost of connectors, connecting members, LVDS transistors / receivers, etc. for connecting both substrates. There is problem to say.

Accordingly, the present invention is directed to an image display apparatus including conversion of a video signal accompanied by an increase in dynamic range, so that the image signal is sent to a signal processing circuit necessary for driving the image display apparatus without increasing the cost for signal transmission. It is an object of the present invention to provide an image display apparatus which can be used.

In order to achieve the above object, the image display device according to the first invention, when converting a video signal of the first video signal format into a video signal of the second video signal format, video signal conversion accompanied with an increase in the dynamic range An image display apparatus for performing an image processing, comprising: a video signal conversion circuit for inputting a video signal of the first video signal format and converting and outputting a video signal of the second video signal format; And a signal processing module including a drive circuit for driving a display panel and a signal processing circuit for performing signal processing necessary for driving the drive circuit, wherein the video signal conversion circuit is provided in the signal processing module. .

As a result, in an image display device for converting a video signal accompanied by an increase in dynamic range, transmission between modules of a video signal having increased dynamic range after conversion is unnecessary, thereby driving the image display panel without increasing the cost for the transmission. You can.

2nd invention is the image display apparatus which concerns on 1st invention, The said signal processing module is a board | substrate or an ASIC, It is characterized by the above-mentioned.

As a result, the signal processing in the signal processing module is performed in the same substrate or in the same ASIC, so that the transmission of the signal with the increased dynamic range becomes unnecessary, and the cost increase for the transmission can be prevented.

In a third aspect of the invention, in the image display apparatus according to the first or second invention, the video signal of the first video signal format is a YCbCr signal, and the video signal of the second video signal format is an RGB signal.

Thereby, an image display panel of an RGB input format can be driven without increasing the transmission cost for a plasma display device or a liquid crystal display device that requires color coordinate conversion from a YCbCr signal to an RGB signal.

In a fourth aspect of the invention, in the image display apparatus according to any one of the first to third aspects, the image display panel is a plasma display panel, and the signal processing circuit includes a subfield conversion circuit.

As a result, the signal transmission between the subfield conversion circuit and the video signal conversion circuit peculiar to the driving of the plasma display panel is performed in the same signal processing module, so that the signal with increased dynamic range between the video signal conversion circuit and the subfield conversion circuit. The transmission can be prevented.

5th invention is the image display apparatus which concerns on 4th invention, The said signal processing circuit is characterized by including the reverse (gamma) correction circuit.

Thereby, the signal processing can be performed in the same signal processing circuit mounted in the same signal processing module, without performing signal transmission with an increased dynamic range, which is preferably provided for driving the plasma display panel.

A sixth invention is the image display device according to the fourth or fifth invention, wherein the signal processing circuit includes a color matrix circuit.

Thereby, the color adjustment of an image can be performed in the same signal processing circuit mounted in the same signal processing module, without performing the transmission of the signal with the increased dynamic range.

A seventh invention is the image display device according to any one of the fourth to sixth aspects, wherein the signal processing circuit includes a back balance correction circuit.

Thereby, the back balance correction of an image can be performed in the same signal processing circuit mounted in the same signal processing module, without performing the transmission of the signal with the increased dynamic range.

An image display device according to an eighth aspect of the invention is an image display device for converting a video signal in a first video signal format into a video signal in a second video signal format having increased dynamic range, and performing video signal conversion. A video signal conversion circuit for inputting a video signal in one video signal format and converting and outputting a video signal in the second video signal format, a driving circuit for driving an image display panel with the video signal in the second video signal format; And a signal processing module including a signal processing circuit for performing signal processing necessary for driving the drive circuit, wherein the video signal conversion circuit is provided in the signal processing module, and an input video signal of the signal processing module is connected to the first signal processing module. It is characterized by the video signal format.

According to the present invention, even in an image display apparatus including conversion of a video signal accompanied by an increase in dynamic range, it is possible to prevent an increase in transmission bits between modules in the image display apparatus, thereby preventing an increase in cost for transmission. have.

EMBODIMENT OF THE INVENTION Hereinafter, the best form for implementing this invention is demonstrated with reference to drawings.

1 is a circuit block diagram of an image display device 150 according to an embodiment to which the present invention is applied. In FIG. 1, the image display device 150 according to the present embodiment includes a television signal processing circuit 10, a video signal conversion circuit 20, a signal processing circuit 70, and an image display panel driving circuit 80. ) And an image display panel 90. The video signal conversion circuit 20 and the signal processing circuit 70 are provided in the same signal processing module 100. In addition, the television signal processing circuit 10, the image display panel drive circuit 80, and the image display panel 90 do not need to be in the same signal processing module 100, and may be connected by LVDS, a connection line, or the like. .

The television signal processing circuit 10 is a circuit for processing the input television video signal. As the signal processing, for example, the density and the color of the color are adjusted, or a process such as reduction or enlargement of the screen matched with the image display panel 90 is performed. In this case, when the video signal is input in the YCbCr format, for example, the signal processing can be performed in the YCbCr format. Therefore, the signal processing is performed in the YCbCr format.

The video signal conversion circuit 20 converts the video signal of the first video signal format output from the television signal processing circuit 10 into a video signal of a second video signal format different from the first video signal format. To convert the video signal format. For example, when the video signal input to the video signal conversion circuit 20 is a YCbCr signal and the video signal output from the video signal conversion circuit 20 is an RGB signal, the video signal conversion circuit 20 is YCbCr / RGB. A conversion circuit may be applied. Hereinafter, the present embodiment will be described taking YCbCr / RGB conversion as an example. However, the present embodiment is also applicable to other video signal conversions involving an increase in dynamic range, but the present invention is not limited thereto.

Here, for example, when a YCbCr format video signal is input in 10 bits, the RGB signal remains 10 bits when signal conversion is performed in the conventional color gamut. However, when a wide area video signal to which the xvYCC standard is applied is input, it is converted to an RGB signal, so that a negative signal or one or more RGB signals are output, and the dynamic range is increased by about three times. Therefore, if the RGB signal is to be transmitted while maintaining the image level as in the prior art, the required signal bit width is increased by 2 bits and 12 bits are required.

Here, an example of the conversion equation of the YCbCr / RGB video signal conversion circuit 20 according to the ITU-R BT.709 standard is given by Equation (1).

Similarly, an example of a conversion equation of the YCbCr / RGB video signal conversion circuit 20 according to the ITU-R BT.601 standard is given by Equation 2 below.

When the RGB signal is transmitted after the YCbCr / RGB conversion performed by the YCbCr / RGB video signal conversion circuit 20, the LVDS and the connection member used for the signal transmission are processed corresponding to the increase in the dynamic range. It will be necessary to carry out. However, in the image display device 150 according to the present embodiment, since the signal processing circuit 70 that performs the following processing is provided in the same signal processing module 100, there is no need to perform signal transmission, and therefore the same The necessary signal processing is performed in the signal processing module 100.

The signal processing module 100 is a module that integrally constitutes various circuits. For example, a circuit board mounted in an image display device or an application specific integrated circuit (ASIC) may be applied. As a result, a series of signal processing can be performed in circuit without transmitting the RGB signal output from the YCbCr / RGB video signal conversion circuit 20 to the signal processing circuit 70 by using LDVS or the like.

In addition, the YCbCr / RGB conversion performed in the YCbCr / RGB video signal conversion circuit 20 according to the present embodiment means not a simple increase in the number of bits but a YCbCr / RGB conversion involving an increase in the dynamic range. That is, even if the conventional YCbCr / RGB conversion does not involve an increase in the dynamic range, the YCbCr (4: 2: 2) method in which the transmission clock rate of color is compressed to 1/2 at the time of YCbCr signal transmission is used. In the case of application, since the information of the CbCr (color signal) is transmitted only once in two pixels, the YCbCr signal is transmitted in two-thirds of the bits compared with the case where there is no compression. When the YCbCr signal is converted to an RGB signal after transmission, the Y (luminance) signal is used, and therefore, the number of bits before compression is returned. That is, for example, when the YCbCr signal, which was 24 bits in the YCbCr (4: 4: 4) system without compression, is transmitted in the YCbCr (4: 2: 2) system as described above, it becomes 16 bits. When the 16-bit YCbCr signal is converted to YCbCr / RGB, the signal is returned to 24 bits again, accompanied by an increase in the number of bits. However, in such a YCbCr / RGB conversion, the number of bits increases, but the dynamic range does not increase at all. The YCbCr / RGB conversion performed in the YCbCr / RGB video signal conversion circuit 20 in the present embodiment means a video signal conversion accompanied by an increase in the dynamic range to the last. This is different from increasing the number of bits. Thus, by combining with the scheme of the present invention, it becomes possible to further compress the transmission bit width of the video signal.

In the signal processing circuit 70, signal processing peculiar to the type of the image display panel 90 required for the image display panel drive circuit 80 for driving the image display panel 90 is performed. For example, when the image processing panel 90 is a plasma display panel, the signal processing circuit 70 may include a subfield conversion circuit, a signal conversion circuit that conforms to the input signal specification of the panel driver, or the like. In the case where the image display panel 90 is a liquid crystal display panel, a signal processing circuit 70 including a signal conversion circuit according to an input signal specification of a panel driver required for driving the liquid crystal display panel may be provided.

The image display panel drive circuit 80 is a drive control circuit for driving the image display panel 90, and a drive control circuit according to the type of the image display panel 90 may be applied.

The image display panel 90 may be, for example, a plasma display panel, a liquid crystal display panel, or the like as display means for displaying an image.

As described above, in the image display device 150 according to the present embodiment, the video signal conversion circuit 20 is incorporated in a signal processing module equipped with the signal processing circuit 70, and the YCbCr is provided from the television signal processing circuit 10. As it is possible to transmit and input directly as a signal, even if a YCbCr format video signal including wide-area video information is transmitted, the YCbCr signal with a low transmission rate is transmitted as it is, and the signal processing is performed circuitally after conversion to an RGB signal. As a result, the RGB signal with increased dynamic range is not transmitted, and the cost can be prevented from being increased.

Next, with reference to FIG. 2, the specific Example at the time of applying the plasma display apparatus 150a to the image display apparatus 150 is demonstrated. 2 is a circuit block diagram of the plasma display device 150a according to the present embodiment. In addition, the same code | symbol is attached | subjected to the component similar to the image display apparatus 150 which concerns on FIG. 1, and the description is abbreviate | omitted or simplified.

In FIG. 2, the plasma display device 150a according to the present embodiment includes a television signal processing circuit 10, a signal processing module 100a, a plasma display panel driving circuit 80a, and a plasma display panel 90a. It includes. The signal processing module 100a includes a YCbCr / RGB video signal conversion circuit 20 and a signal processing circuit 70a. In addition, the signal processing circuit 70a may include an inverse gamma correction circuit 30, a color matrix circuit 40, a back balance correction circuit 50, and a subfield conversion circuit 60.

In the plasma display device 150a of FIG. 2, the signal processing circuit 70a includes an inverse gamma correction circuit 30, a color matrix circuit 40, and a back, compared to the image display device 150 of FIG. 1. The balance correction circuit 50 and the subfield conversion circuit 60 are different from each other in that they are specifically provided. As a matter of course, the plasma display panel 90a is applied to the image display panel 90, and the plasma display panel driving circuit 80a is applied thereto.

The television signal processing circuit 10 is the same as that described in the embodiment according to FIG. 1, and in the plasma display device 150a, the YCbCr signal is input, and the YCbCr signal is processed as it is. Processing such as enlargement and reduction of an image is performed.

The YCbCr / RGB video signal conversion circuit 20 is also similar to the description in the embodiment according to FIG. 1, and the YCbCr signal is input from the television signal processing circuit 10 in a state where the transmission rate is not enlarged. The input YCbCr signal is converted into an RGB signal in accordance with the conversion formula (1) or (2), and converted into an RGB signal in which 2 bits of the dynamic range increase is increased from the YCbCr signal. For example, if the input YCbCr signal is 10 bits, a 12-bit RGB signal is output. The output RGB signal is input to the signal processing circuit 70a in the same signal processing module 100.

The signal processing circuit 70a is a circuit that performs signal processing necessary for driving the plasma display panel driving circuit 80a for driving control of the plasma display panel 90a. The signal processing circuit 70a performs signal processing peculiar to the plasma display apparatus 150a. It is a circuit to perform. Among the signal processing circuits 70a peculiar to the plasma display device 150a, the subfield conversion circuit 60 is essential. In addition, the reverse gamma correction circuit 30, the color matrix circuit 40, and the back balance correction circuit 50 may be provided as needed. Hereinafter, each circuit 30, 40, 50, 60 of the signal processing circuit 70a will be described in order.

The inverse gamma correction circuit 30 is a signal characteristic correction circuit for correcting the inverse of returning this to the video signal inputted after transmission gamma correction and making the output signal a linear characteristic.

3 is a diagram for explaining the function of the inverse gamma correction circuit 20. In FIG. 3, the input signal is x and the output signal is y.

FIG. 3A is a diagram showing signal characteristics of a transmission? -Corrected video signal input to an inverse? Correction circuit. In Fig. 3A, the transmission? -Corrected video signal exhibits the upwardly convex rising characteristic.

3B is a correction characteristic diagram of the inverse gamma correction circuit 30. The inverse gamma correction circuit corrects the input signal x with the characteristic of y = x ^2.2 and outputs the output signal y. This is not necessary to perform such correction when the image display panel 90 is a cathode ray tube in accordance with the characteristics of the cathode ray tube, but since the plasma display panel 90a has a linear output characteristic, such a correction circuit allows You may correct as needed.

FIG. 3C is a diagram showing signal characteristics of the output video signal of the inverse gamma correction circuit 30. As shown in FIG. In FIG. 3C, it is shown that the input signal and the output signal have linear characteristics. Thus, the video signal corrected by the linear characteristic by the reverse gamma correction circuit 30 is input to the color matrix circuit 40.

The color matrix circuit 40 is a circuit for performing coordinate transformation for color reproduction when signal conversion is performed in the YCbCr / RGB video signal conversion circuit 20.

4 is a diagram for explaining the function of the color matrix circuit 40. 4 is a view for explaining the function of the color matrix circuit in the case where the color reproduction range of the plasma display panel 90a is wider than the color reproduction range according to the standard of the input color video signal.

In FIG. 4, the green (G) signal will be described as an example. If the G ₀ signal of the input color video signal corresponding to ITU-R BT.709 is supplied to the plasma display panel 90a as it is, the G ₀ signal is displayed at the outermost corner G of the color reproduction range 95 of the plasma display panel 90a. Is reproduced. However, this G ₀ signal must be reproduced as the color of the position of G 'within the range of the original color reproduction range 95. Therefore, the component (K _GR G) of the input signal R multiplied by (K _GR ) times (K _GR > 0) and the input signal B by _{multiplying the} input signal G (K _GB ) times (K _GB > O) The vector (K _GB G) is summed together to form a G 'signal, which is matched with the chromaticity value of the G ₀ signal. Such correction is also performed for other blue signals B and red signals R to obtain B 'and R' signals. When wide color gamuted by the xvYCC standard, the value of RGB can also take a negative value, so that it exceeds the color reproduction range represented by R'G'B 'to the color reproduction range 95 of the plasma display panel 90a. You will be able to reproduce colors correctly.

5 is a block diagram showing an example of the configuration of the color matrix circuit 40. In FIG. 5, the color matrix circuit 40 receives a green (G) signal SG, a blue (B) signal SB, and a red (R) signal SR as an input color image signal, and performs color correction as described in FIG. 4. The correction signals SG ', SB', and SR 'are output.

The color matrix circuit 40 shown in FIG. 5 performs correction processing as shown in equation (3).

only,

K _BG : Mixing coefficient of B signal to G signal

K _RG : Mixing coefficient of R signal to G signal

K _GB : Mixing coefficient of G signal for B signal

K _RB : Mixing coefficient of R signal to B signal

K _GR : mixing coefficient of G signal to R signal

K _BR : Mixing coefficient of B signal to R signal

The circuit of FIG. 5 is a circuit for performing color correction as described with reference to FIG. 4. For example, in FIG. 4, only the G signal is noted, which corresponds to the case of SB = 0 and SR = 0. From equation 3,

The correction as shown in Fig. 4 is reliably performed.

Returning to FIG. 2, the back balance correction circuit 50 will be described. The back balance correction circuit 50 is a circuit for changing the gain ratio of the RGB signal. That is, when white color is displayed, it is a circuit which changes and adjusts the gain ratio of an RGB signal based on whether it is reddish white or blueish white.

6 is a block diagram illustrating an example of the back balance correction circuit 50. In FIG. 6, the back balance correction circuit 50 is composed of multipliers 51, 52, 53, and a microcomputer 55. As shown in FIG. 6, the back balance correction circuit 50 performs multiplication coefficients from the microcomputer 55 by the multipliers 51, 52, 53 on the input video signals R, G, and B. Amplitude coefficient) Multiplies Kr, Kg, and Kb. That is, the microcomputer 55 multiplies the coefficients Kr, Kg, and Kb for the video signals R, G, and B of each color in order to correct or adjust the back balance by changing the luminance ratios of red, green, and blue. , 53). Here, the coefficients Kr, Kg, and Kb may be the same depending on the video signals R, G, and B of each color, and may be different from each other. That is, the back balance correction circuit 50 supplies coefficients Kr, Kg, and Kb from the microcomputer 55 to the multipliers 51, 52, 53, and the signal amplitudes of the video signals R, G, and B of each color. The back balance is corrected by controlling.

Here, in the back balance correction circuit 50, in order to adjust the back balance, for example, a signal of the video signals R, G, and B of each color is displayed so as to display an arbitrary constant adjustment pattern so as to obtain a desired back balance. The amplitude adjustment may be performed. That is, for example, before the factory shipment, the back balance is adjusted or corrected for each plasma display device 150a, but a constant adjustment pattern is displayed, and the coefficients Kr, Kg, and Kb are set in the microcomputer 55 in the state. By doing so, a desired back balance can be obtained.

Returning to FIG. 2, the subfield conversion circuit 60, the plasma display panel drive circuit 80a, and the plasma display panel 90a which are the components unique to the plasma display apparatus 150a are demonstrated. Since these operations are interlocked with respect to these three components, it demonstrates collectively.

FIG. 7 is a block diagram schematically showing an example of a portion of the subfield conversion circuit 60, the plasma display panel drive circuit 80a, and the plasma display panel 90a of the plasma display apparatus 150a. In Fig. 7, the plasma display device 150a includes a plasma display panel 90a, an address electrode 91, a scan sustain electrode 92, a sustain electrode 93, a partition 99, and an address drive. A circuit 81, a scan sustain pulse output circuit 82, a sustain pulse output circuit 83, a drive control circuit 85, and a subfield conversion circuit 60 are provided.

As shown in FIG. 7, the plasma display device 150a is roughly divided into three types: the plasma display panel 90a, the plasma display panel driving circuit 80a, and the subfield conversion circuit 60. The plasma display panel 90a includes an address electrode 91, a scan sustain electrode 92, a sustain electrode 93, and a partition 99. The plasma display panel drive circuit 80a includes an address drive circuit 81 for driving the address electrode 91, a scan sustain pulse output circuit 82 for driving the scan sustain electrode 92, and a sustain electrode 93. A sustain pulse output circuit 83 for driving the circuit and a drive control circuit 85 for controlling these output circuits. The subfield conversion circuit 60 has a circuit for performing subfield conversion signal processing of an input video signal. In addition, the subfield conversion circuit 60 is configured as part of the signal processing module 100a.

Here, in the plasma display panel 90a, the address electrode 91 is provided on one side of the two glass substrates facing each other, and the scan sustain electrode 92 is provided on the other side. The spaces provided between these glass substrates are partitioned by the partition walls 99, and each of the partitioned spaces constitutes a discharge cell. For example, rare gases, such as He-Xe and Ne-Xe, are sealed in the discharge cells. When voltage is applied to the scan sustain electrodes 92 and the sustain electrodes 93, discharge occurs and ultraviolet rays are generated. In addition, each discharge cell is coated with a phosphor that emits light of any one of red, green, and blue, and the ultraviolet light generated as described above excites the phosphor to emit color light corresponding to each phosphor. By using this light emission, color image display can be performed by selecting discharge cells of a desired color in accordance with a video signal.

In addition, the drive control circuit 85 controls the number of times of light emission of the video signal through the scan sustain pulse output circuit 82 in accordance with the display ratio (or display current) of the image by the video signal (RGB signal).

FIG. 8 is a view for explaining an example of the driving sequence of the plasma display apparatus 150a in FIG. 7 and is for explaining the subfield method using the above-described issue principle.

The subfield method divides one frame into a plurality of subfields (SF1 to SF4 in Fig. 8) weighted according to the difference in the number of emission, and selects a subfield according to the amplitude of a signal therein for each pixel. How to express. The driving sequence by the subfield method shown in FIG. 8 shows an example in the case where 16 frames are displayed by dividing one frame into four subfields SF1 to SF4. It is a period for selecting the scanning period T1ha of each subfield, the discharge cells emitting light in the subfield (hereinafter referred to as "light emitting cells"), and the period in which the discharge sustain period T2ha and the selected light emitting cells emit light. .

The discharge sustain period T2 of the subfields SF1 to SF4 takes time for the selected cell to emit light, and each of them is weighted to the number of emission in a ratio of 8: 4: 2: 1. Then, by arbitrarily selecting any one of these subfields SF1 to SF4 in accordance with the video signal level, it is possible to display the quadratic power of 2 = 16 gray scales. In order to increase the number of gradations, the number of subfields may be increased. For example, when the number of subfields is 8, 8 powers of 2 = 256 gradations can be displayed. In addition, the brightness level of each subfield is controlled by the number of sustain light emission (the number of light emission).

In order to drive the plasma display panel 90a by such a subfield method, the subfield conversion circuit 60 newly creates a bit signal group of each of the plurality of subfields from the input video signal, thereby subfields. It performs a signal conversion process of converting into subfield data indicating light emission and non-emission of light. In addition, in the subfield conversion circuit 60, the converted subfield data is read in the order of SF1, SF2, SF3, and each subfield is read out for each subfield along with the passage of time along the time axis. Change the reading order.

The read subfield data is output to the address driving circuit 81 as address data, and the driving control of the plasma display panel 90a is performed by the plasma display panel driving circuit 80a as described above.

In the example of FIG. 8, each subfield SF1 to SF4 is weighted to the number of light emission in a binary ratio of 8: 4: 2: 1, but may be weighted to the number of light emission at any ratio.

Returning to FIG. 2, as described so far, the signal processing circuits required for the specific driving of the plasma display device 150a are the sub-field conversion circuits 60, and the signal processing circuits 70a including the same; By embedding the YCbCr / RGB video signal conversion circuit 20 into one signal processing module 100a, subfield conversion of the final stage in the same signal processing module is performed without transmitting the video signal cable having increased dynamic range. Video signals can be sent to the circuit 60.

In addition, the inverse gamma correction circuit 30, the color matrix circuit 40, the back balance correction circuit 50, the subfield conversion circuit 60, and the plasma display described above as components unique to the plasma display device 150a are also described. Various aspects may be applied to the respective configurations of the panel driving circuit 80a and the plasma display panel 90a, and the aspects described in this embodiment are merely examples, and are not intended to be limiting.

The inverse gamma correction circuit 30, the color matrix circuit 40, and the back balance circuit 50 are not necessarily required as signal processing for driving the plasma display apparatus 150a. In the case where some or all of these circuits are provided, the signal processing can be performed in a space-saving manner by integrally configuring the signal processing circuit 70a in the signal processing module 100a. In particular, since the inverse gamma correction circuit 30 performs signal processing in which the number of bits of the output signal increases with respect to the input signal, the inverse gamma correction circuit 30 has a significant meaning by the configuration of the plasma display device 150a according to the present embodiment. The YCbCr / RGB video signal conversion circuit 20, the inverse gamma correction circuit 30, the color matrix circuit 40, the back balance correction circuit 50, and the subfield conversion circuit 60 are connected to one signal processing module 100a. ), High-speed signal processing can be realized while saving space at low cost.

As mentioned above, although preferred embodiment of this invention was described in detail, this invention is not limited to the above-mentioned embodiment, A various deformation | transformation and substitution are possible for the above-mentioned embodiment, without deviating from the range of this invention. Do.

1 is a circuit block diagram of an image display device 150 according to an embodiment to which the present invention is applied.

2 is a circuit block diagram of the plasma display device 150a according to the present embodiment.

FIG. 3 is a diagram for explaining the function of the reverse gamma correction circuit 20, and FIG. 3A is a diagram showing signal characteristics of the transmission gamma-corrected video signal input to the reverse gamma correction circuit. 3B is a diagram showing correction characteristics of the inverse gamma correction circuit 30, and FIG. 3C is a diagram showing signal characteristics of the output video signal of the inverse gamma correction circuit 30;

4 is a diagram for explaining the function of the color matrix circuit 40. FIG.

5 is a block diagram illustrating an example of a configuration of the color matrix circuit 40.

6 is a block diagram illustrating an example of the back balance correction circuit 50.

7 is a block diagram schematically showing a part of the plasma display device 150a.

8 is a view for explaining an example of a drive sequence of the plasma display device 150a.

9 is a photoelectric conversion characteristic diagram of a known ITU-R BT.709 standard and an xvYCC ₇₀₉ standard;

10 is a conceptual diagram showing a color gamut of a known video signal.

11 is a circuit block diagram of a conventional plasma display device 250.

<Explanation of symbols for the main parts of the drawings>

10: television signal processing circuit

20: video signal conversion circuit

30: reverse gamma correction circuit

40: color matrix circuit

50: back balance correction circuit

60: subfield conversion circuit

70, 70a: signal processing circuit

80: image display panel drive circuit

80a: Plasma Display Panel Drive Circuit

90: image display panel

90a: Plasma Display Panel

100, 100a: signal processing module

150: image display device

150a: plasma display device

Claims (8)

An image display apparatus for converting and displaying a video signal of a first video signal format into a video signal of a second video signal format in which a dynamic range is increased. A video signal conversion circuit for inputting a video signal of the first video signal format and converting and outputting a video signal of the second video signal format; A driving circuit for driving an image display panel with a video signal of the second video signal format; A signal processing module including a signal processing circuit for performing signal processing necessary for driving the driving circuit With And the video signal conversion circuit is provided in the signal processing module. The method of claim 1, The signal processing module is a substrate or an ASIC. The method of claim 1, And the video signal of the first video signal format is a YCbCr signal, and the video signal of the second video signal format is an RGB signal. The method of claim 3, And the image display panel is a plasma display panel, and the signal processing circuit includes a subfield conversion circuit. The method of claim 4, wherein The signal processing circuit includes an inverse gamma correction circuit. The method of claim 5, And the signal processing circuit includes a color matrix circuit. The method of claim 6, The signal processing circuit includes a back balance correction circuit. An image display device for converting a video signal of a first video signal format into a video signal of a second video signal format having a dynamic range which is displayed and converting the video signal. A video signal conversion circuit for inputting a video signal of the first video signal format and converting and outputting a video signal of the second video signal format; A driving circuit for driving an image display panel with an image signal of the second image signal format; A signal processing module including a signal processing circuit for performing signal processing necessary for driving the drive circuit; And the video signal conversion circuit is provided in the signal processing module, and the input video signal of the signal processing module is the first video signal format.

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